Virtual and real object recording in mixed reality device

ABSTRACT

A virtual image generation system for use by an end user comprises memory, a display subsystem, an object selection device configured for receiving input from the end user and persistently selecting at least one object in response to the end user input, and a control subsystem configured for rendering a plurality of image frames of a three-dimensional scene, conveying the image frames to the display subsystem, generating audio data originating from the at least one selected object, and for storing the audio data within the memory.

RELATED APPLICATION DATA

The present application is a continuation of U.S. patent applicationSer. No. 15/907,115, filed on Feb. 27, 2018, entitled “VIRTUAL AND REALOBJECT RECORDING IN MIXED REALITY DEVICE”, which claims priority to U.S.provisional patent application Ser. No. 62/464,757, filed Feb. 28, 2017.The foregoing applications are hereby incorporated by reference into thepresent application in their entirety.

FIELD OF THE INVENTION

The present invention generally relates to virtual reality and augmentedreality systems.

BACKGROUND

Modern computing and display technologies have facilitated thedevelopment of mixed reality systems for so called “virtual reality” or“augmented reality” experiences, wherein digitally reproduced images orportions thereof are presented to a user in a manner wherein they seemto be, or may be perceived as, real. A virtual reality, or “VR”,scenario typically involves presentation of digital or virtual imageinformation without transparency to actual real-world visual input. Anaugmented reality, or “AR”, scenario typically involves presentation ofdigital or virtual image information as an augmentation to visualizationof the actual world around the user (i.e., transparency to other actualreal-world visual input). Accordingly, AR scenarios involve presentationof digital or virtual image information with transparency to otheractual real-world visual input.

For example, referring to FIG. 1, an augmented reality scene 4 isdepicted wherein a user of an AR technology sees a real-world park-likesetting 6 featuring people, trees, buildings in the background, and aconcrete platform 8. In addition to these items, the end user of the ARtechnology also perceives that he “sees” a robot statue 10 standing uponthe real-world platform 8, and a cartoon-like avatar character 12 flyingby which seems to be a personification of a bumble bee, even thoughthese elements 10, 12 do not exist in the real world. As it turns out,the human visual perception system is very complex, and producing a VRor AR technology that facilitates a comfortable, natural-feeling, richpresentation of virtual image elements amongst other virtual orreal-world imagery elements is challenging.

VR and AR systems typically employ head-worn displays (or helmet-mounteddisplays, or smart glasses) that are at least loosely coupled to auser's head, and thus move when the end user's head moves. If the enduser's head motions are detected by the display system, the data beingdisplayed can be updated to take the change in head pose (i.e., theorientation and/or location of user's head) into account. Head-worndisplays that enable AR (i.e., the concurrent viewing of virtual andreal objects) can have several different types of configurations. In onesuch configuration, often referred to as a “video see-through” display,a camera captures elements of a real scene, a computing systemsuperimposes virtual elements onto the captured real scene, and anon-transparent display presents the composite image to the eyes.Another configuration is often referred to as an “optical see-through”display, in which the end user can see through transparent (orsemi-transparent) elements in the display system to view directly thelight from real objects in the environment. The transparent element,often referred to as a “combiner,” superimposes light from the displayover the end user's view of the real world.

Oftentimes, a user of a VR/AR system may want to share his or herexperience with others (e.g., when playing a game, teleconferencing, orwatching a movie) by recording and saving the experience on the VR/ARsystem for subsequent publishing on-line. However, there may typicallybe noise and other unwanted or unexpected sounds in the recording due toa noisy environment or there may otherwise be too many sources of soundthat cause distractions to the experience. Such unwanted/unexpectedsounds may originate from real objects, e.g., from children playing inthe vicinity the VR/AR system, or from virtual objects, e.g., from avirtual television playing in the context of the VR/AR system.

There, thus, remains a need to provide a simple and efficient means forrecording sounds from only virtual or real objects that the user isinterested in.

SUMMARY

In accordance with a first aspect of the present inventions, a virtualimage generation system for use by an end user comprises memory, adisplay subsystem, and an object selection device configured forreceiving input from the end user and persistently selecting at leastone object (e.g., a real object and/or a virtual object) in response tothe end user input. In one embodiment, the display subsystem has a fieldof view, and the object selection device is configured for persistentlyselecting the object(s) in the field of view. In this case, the objectselection device may be configured for moving a three-dimensional cursorin the field of view of the display subsystem and selecting theobject(s) in response to receiving the end user input. In anotherembodiment, the end user input comprises one or more voice commands, andwherein the object selection device comprises one or more microphonesconfigured for sensing the voice command(s). In still anotherembodiment, the end user input comprises one or more hand gestures, inwhich case, the object selection device may comprise one or more camerasconfigured for sensing the hand gesture(s).

In the case where a plurality of objects is selected, the objectselection device may be configured for individually selecting and/orglobally selecting the objects in response to the end user input. Ifglobally selected, the object selection device may be configured forglobally selecting all objects in an angular range of the field of view(which may be less than the entire angular range of the field of view ormay be the entire angular range of the field of view) in response to theend user input. In one embodiment, the object selection device isfurther configured for receiving another input from the end user andpersistently deselecting the previously selected object(s) in responseto the other end user input.

The virtual image generation system further comprises a controlsubsystem configured for generating video data originating from the atleast one selected object, rendering a plurality of image frames in athree-dimensional scene from the video data, and conveying the imageframes to the display subsystem. In one embodiment, the displaysubsystem is configured for being positioned in front of the eyes of theend user. In another embodiment, the display subsystem includes aprojection subsystem and a partially transparent display surface. Inthis case, the projection subsystem may be configured for projecting theimage frames onto the partially transparent display surface, and thepartially transparent display surface may be configured for beingpositioned in the field of view between the eyes of the end user and anambient environment. The virtual image generation system may furthercomprise a frame structure configured for being worn by the end user,and carrying at least a portion of the display subsystem.

The control subsystem is further configured for generating audio dataoriginating from the selected object(s), and for storing the audio datawithin the memory. The virtual image generation system may furthercomprise a plurality of speakers, in which case, the control subsystemmay be further configured for conveying the generated audio data to thespeakers. In an optional embodiment, the control subsystem is furtherconfigured for storing the video data in synchronization with the audiodata in the memory. In still another embodiment, the virtual imagegeneration system further comprises at least one sensor configured fortracking a location of the selected object(s) relative to the field ofview of the display subsystem. In this case, the control subsystem maybe configured for ceasing to store the audio data in the memory when thetracked location of the selected object(s) moves out of the field ofview of the display subsystem, or alternatively, is configured forcontinuing to store the audio data in the memory when the trackedlocation of the selected object(s) moves out of the field of view of thedisplay subsystem.

If the selected object(s) comprises a real object, the virtual imagegeneration system may further comprise a microphone assembly configuredfor generating an audio output, in which case, the control subsystem maybe further configured for modifying the direction audio output topreferentially sense sounds originating from the selected real object.The audio data may be derived from the modified audio output.

The virtual image generation system may further comprise one or morecameras configured for capturing video data originating from theselected real object, in which case, the control subsystem may befurther configured for storing the video data in synchronization withthe audio data in the memory. The control subsystem may be configuredfor transforming the captured video data into virtual content data forthe selected real object, and storing the virtual content in the memory.

If the selected object(s) comprises a virtual object, the virtual imagegeneration system may further comprise a database configured for storingcontent data corresponding to sounds for a plurality of virtual objects,in which case, the control subsystem may be further configured foracquiring the content data corresponding to the selected virtual objectfrom the database, and the audio data stored in the memory comprises theacquired content data. The control subsystem may be further configuredfor generating meta data corresponding to the selected virtual object(e.g., position, orientation, and volume data for the selected virtualobject), in which case, the audio data stored in the memory may comprisethe acquired content data and generated meta data. In one embodiment,the virtual image generation system further comprises one or moresensors configured for tracking a head pose of the end user, in whichcase, the database may be configured for storing absolute meta data forthe plurality of virtual objects, and the control subsystem may befurther configured for generating the meta data by acquiring theabsolute meta data corresponding to the selected virtual object, andlocalizing the absolute meta data to the end user based on the trackedhead pose of the end user.

The virtual image generation system may further comprise at least onespeaker, in which case, the control subsystem may be further configuredfor retrieving the stored audio data from the memory, deriving audiofrom the retrieved audio data, and conveying the audio to thespeaker(s). The audio data stored in the memory may comprise contentdata and meta data, in which case, the control subsystem may be furtherconfigured for retrieving the stored content data and meta data from thememory, rendering spatialized audio based on the retrieved content dataand meta data, and the conveying the rendered spatialized audio to theat speaker(s).

In accordance with a second aspect of the present inventions, a methodof operating a virtual image generation system by an end user isprovided. The method comprises persistently selecting at least oneobject (e.g., a real object and/or a virtual object). In one method,selecting the object(s) comprises moving a three-dimensional cursor inthe field of view of the end user and selecting the object(s) with thethree-dimensional cursor. In another method, selecting the object(s)comprises issuing one or more voice command. In still another method,selecting the at least one object comprises making one or more handgestures. If a plurality of objects is selected, selecting the pluralityof objects may comprise individually selecting the objects and/orglobally selecting the objects. If globally selected, the objects may beselected by defining an angular range of a field of view of the end user(which may be less than the entire angular range of the field of view ormay be the entire angular range of the field of view), and selecting allof the objects in the defined angular range of the field of view of theend user. An optional method may further comprise persistentlydeselecting the previously selected object(s).

The method further comprises generating video data originating from theselected object(s), rendering a plurality of images frames in athree-dimensional scene from the generated video data, and displayingthe image frames to the end user, generating audio data originating fromthe at least one selected object, and storing the audio data originatingfrom the at least one selected object within memory. One method mayfurther comprise transforming the audio data originating from theselected object(s) into sound for perception by the end user. The methodmay optionally comprise storing the video data in synchronization withthe audio data in the memory. Still another method may further comprisetracking a location of the selected object(s) relative to a field ofview of the end user. In this case, method may further comprise ceasingto store the audio data in the memory when the tracked location of theselected object(s) moves out of the field of view of the end user, oralternatively, continuing to store the audio data in the memory when thetracked location of the selected object(s) moves out of the field ofview of the end user.

If the selected object(s) comprises a real object, the method mayfurther comprise preferentially sensing sounds originating from theselected real object relative to sounds originating from other realobjects, in which case, the audio data may be derived from thepreferentially sensed sounds. The method may further comprise capturingvideo data originating from the selected real object, and storing thevideo data in synchronization with the audio data in the memory. Thecaptured video data may be transformed into virtual content data forstorage in the memory.

If the selected object(s) comprises a virtual object, the method mayfurther comprise storing content data corresponding to sounds for aplurality of virtual objects, and acquiring the content datacorresponding to the selected virtual object, in which case, the audiodata stored in the memory may comprise the acquired content data. Themethod may further comprise generating meta data corresponding to theselected virtual object (e.g., position, orientation and volume data forthe selected virtual object), in which case, the audio data stored inthe memory may comprise the acquired content data and the generated metadata. The method may further comprise tracking a head pose of the enduser, and storing absolute meta data for the plurality of virtualobjects. In this case, generating the meta data may comprise retrievingthe absolute meta data corresponding to the selected virtual object, andlocalizing the absolute meta data to the end user based on the trackedhead pose of the end user.

The method may further comprise retrieving the stored audio data,deriving audio from the retrieved audio data, and transforming the audiointo sound for perception by the end user. The stored audio data maycomprise content data and meta data, in which case, the method mayfurther comprise retrieving the stored content data and meta data fromthe memory, rendering spatialized audio based on the retrieved contentdata and meta data, and transforming the spatialized audio into soundfor perception by the end user.

In accordance with a third aspect of the present inventions, a virtualimage generation system for use by a playback user is provided. Thevirtual image generation system comprises memory configured for storingaudio content data and video content data originating from at least oneobject (e.g., a real object and/or a virtual object) in an originalspatial environment, a plurality of speakers, and a display subsystem.In one embodiment, the display subsystem is configured for beingpositioned in front of the eyes of the end user. In another embodiment,the display subsystem includes a projection subsystem and a partiallytransparent display surface. In this case, the projection subsystem maybe configured for projecting the image frames onto the partiallytransparent display surface, and the partially transparent displaysurface may be configured for being positioned in the field of viewbetween the eyes of the end user and an ambient environment. The virtualimage generation system may further comprise a frame structureconfigured for being worn by the end user, and carrying at least aportion of the display subsystem.

The virtual image generation system further comprises a controlsubsystem configured for retrieving the audio content data and videocontent data from the memory, respectively rendering audio and videofrom the retrieved audio content data and video content data in a newspatial environment different from the original spatial environment, andsynchronously conveying the rendered audio to the speakers and thegenerated video data to the display subsystem.

In one embodiment, the control subsystem is configured for storing theaudio content data and video content data in the memory. The virtualimage generation system may further comprise an object selection deviceconfigured for receiving input from an end user and persistentlyselecting the object(s) in the original spatial environment in responseto the end user input prior to storage of the audio content data andvideo content data in the memory.

If the object(s) comprises a real object, the virtual image generationsystem may further comprise a microphone assembly configured forcapturing the audio content data from the real object in the originalspatial environment. The microphone assembly may be configured forgenerating an audio output, in which case, the control subsystem may befurther configured for modifying the direction the audio output topreferentially sense sounds originating from the selected real object.The audio content data may be derived from the modified audio output.The virtual image generation system may further comprise one or morecameras configured for capturing the video data from the selected realobject in the original spatial environment. In an optional embodiment,the control subsystem may be configured for transforming the capturedvideo data into virtual content data for the selected real object, andstoring the virtual content data as the video content data in thememory.

If the object(s) comprises a virtual object, the virtual imagegeneration system may further comprise a database configured for storingcontent data corresponding to sounds for a plurality of virtual objects,in which case, the control subsystem may be further configured foracquiring the content data corresponding to the virtual object from thedatabase, and the audio data stored in the memory may comprise theacquired content data.

In one embodiment, the control subsystem is configured for acquiringabsolute meta data corresponding to the at least one object in the newspatial environment, and rendering the audio from the retrieved audiocontent data and the absolute meta data in the new spatial environment.Acquiring the absolute meta data corresponding to the object(s) in thenew spatial environment may comprise positioning the object(s) in thenew spatial environment. In this case, the virtual image generationsystem may further comprise a user input device configured for receivinginput from the playback user, in which case, the control subsystem maybe configured for positioning the object(s) in the new spatialenvironment in response to the input from the playback user. The virtualimage generation system may further comprise one or more sensorsconfigured for tracking a head pose of the playback user, in which case,the control subsystem may be further configured for localizing theabsolute meta data to the playback user based on the tracked head poseof the playback user, such that the rendered audio is spatialized.

In accordance with a fourth aspect of the present inventions, a methodof operating a virtual image generation system by a playback user toplay back audio and video of at least one object (e.g., a real objectand/or virtual object) previously recorded in an original spatialenvironment as audio content data and video content data is provided.The method comprises retrieving the audio content data and video contentdata from memory. One method further comprises storing the audio contentdata and video content data in the memory. In this case, the method mayfurther comprise persistently selecting the object(s) in the originalspatial environment prior to storage of the audio content data and videocontent data in the memory.

If the object comprises a real object, the method may further comprisecapturing the audio content data from the real object. In this case, themethod may further comprise preferentially sensing sounds originatingfrom the selected real object relative to sounds originating from otherreal objects. The audio content data is derived from the preferentiallysensed sounds. The method may further comprise capturing video data fromthe selected real object, and transforming the captured video data intothe virtual content data. If the object comprises a virtual object, themethod may further comprise storing content data corresponding to soundsfor a plurality of virtual objects, and acquiring the content datacorresponding to the virtual object from the database. The audio contentdata stored in the memory may comprise the acquired content data.

The method further comprises respectively rendering audio and video fromthe retrieved audio content data and video content data in a new spatialenvironment different from the original spatial environment,respectively transforming the audio and video into sound and imageframes, and synchronously conveying the sound and image frames to theplayback user. One method further comprises acquiring absolute meta datacorresponding to the object(s) in the new spatial environment, in whichcase, the audio is rendered from the retrieved audio content data andthe absolute meta data in the new spatial environment. The method mayfurther comprise tracking a head pose of the playback user, andlocalizing the absolute meta data to the playback user based on thetracked head pose of the playback user, in which case, the audio may berendered from the retrieved audio content data and the localized metadata in the new spatial environment, such that the rendered audio isspatialized. Acquiring the absolute meta data corresponding to theobject(s) in the new spatial environment may comprise positioning theobject(s) in the new spatial environment, e.g., in response to the inputfrom the playback user.

Additional and other objects, features, and advantages of the inventionare described in the detail description, figures and claims.

BRIEF DESCRIPTION OF THE DRAWINGS

The drawings illustrate the design and utility of preferred embodimentsof the present invention, in which similar elements are referred to bycommon reference numerals. In order to better appreciate how theabove-recited and other advantages and objects of the present inventionsare obtained, a more particular description of the present inventionsbriefly described above will be rendered by reference to specificembodiments thereof, which are illustrated in the accompanying drawings.Understanding that these drawings depict only typical embodiments of theinvention and are not therefore to be considered limiting of its scope,the invention will be described and explained with additionalspecificity and detail through the use of the accompanying drawings inwhich:

FIG. 1 is a picture of a three-dimensional augmented reality scene thatcan be displayed to an end user by a prior art augmented realitygeneration device;

FIG. 2 is a perspective view of an augmented reality system constructedin accordance with one embodiment of the present inventions;

FIG. 3 is a block diagram of the augmented reality system of FIG. 2;

FIG. 4 is a plan view of one embodiment of a spatialized speaker systemused in the augmented reality system of FIG. 2;

FIG. 5 is a plan view illustrating one technique used by the augmentedreality system of FIG. 2 for allowing an end user to individually selectan object;

FIG. 6 is a plan view illustrating another technique used by theaugmented reality system of FIG. 2 for allowing an end user toindividually select an object;

FIG. 7 is a plan view illustrating still another technique used by theaugmented reality system of FIG. 2 for allowing an end user toindividually select an object;

FIG. 8 is a plan view illustrating a technique used by the augmentedreality system of FIG. 2 for allowing an end user to globally selectmultiple objects;

FIG. 9 is a plan view illustrating another technique used by theaugmented reality system of FIG. 2 for allowing an end user to globallyselect multiple objects;

FIG. 10a is a plan view of one technique that can be used to wear theaugmented reality system of FIG. 2;

FIG. 10b is a plan view of another technique that can be used to wearthe augmented reality system of FIG. 2;

FIG. 10c is a plan view of still another technique that can be used towear the augmented reality system of FIG. 2;

FIG. 10d is a plan view of yet another technique that can be used towear the augmented reality system of FIG. 2.

FIG. 11 is a block diagram illustrating the augmented reality system ofFIG. 2 interacting with various exemplary various virtual and realsound;

FIG. 12 is a block diagram illustrating one embodiment of an audioprocessor used in the augmented reality system of FIG. 2;

FIG. 13 is a diagram of memory recording the content data and meta datacorresponding to virtual and real objects selected by the augmentedreality system of FIG. 2;

FIG. 14 is a schematic of a microphone assembly and corresponding audioprocessing modules used in the augmented reality system of FIG. 2 forpreferentially receiving sound from real objects;

FIG. 15a is a plan view of directional patterns generated by an audioprocessor of the augmented reality system of FIG. 2 to preferentiallyreceive sound from two objects having a first orientation relative tothe end user;

FIG. 15b is a plan view of directional patterns generated by an audioprocessor of the augmented reality system of FIG. 2 to preferentiallyreceive sound from the two objects having a second orientation relativeto the end user;

FIG. 16a is a block diagram of objects distributed in an originalspatial environment relative to the end user;

FIG. 16b is a block diagram of the objects of FIG. 17a distributed in anew spatial environment relative to the end user;

FIG. 17 is a flow diagram illustrating one method of operating theaugmented reality system of FIG. 2 to select and record audio and videoof virtual and real objects; and

FIG. 18 is a flow diagram illustrating one method of operating theaugmented reality system of FIG. 2 to playback the audio and videorecorded in FIG. 17 in a new spatial environment.

DETAILED DESCRIPTION

The description that follows relates to display systems and methods tobe used in an augmented reality system. However, it is to be understoodthat while the invention lends itself well to applications in augmentedreality systems, the invention, in its broadest aspects, may not be solimited. For example, the invention can be applied to virtual realitysystems. Thus, while often described herein in terms of an augmentedreality system, the teachings should not be limited to such systems ofsuch uses. The augmented reality system may be operated in the contextof, e.g., a video game, a teleconference with a combination of virtualand real persons, or watching a movie.

The augmented reality system described herein allows an end user torecord audio data originating from at least one object (either virtualor real) persistently selected by the end user. Such recorded audio datacan be subsequently played back by the same or different end user. Thesound originating from the recorded audio data may be played back to thesame or different end user in the real environment in which the audiodata was originally recorded. In addition to recording the content ofthe audio data, meta data characterizing the environment in which theaudio content was originally recorded, as well as the head pose of theend user, may be recorded in association with such audio data, so thatduring playback, audio may be re-rendered and transformed intospatialized sound that is auditorily experienced in the same manner inwhich the end user auditorily experienced the spatialized sound duringthe original recording. Optionally, audio may be re-rendered andtransformed into spatialized sound for perception by the same ordifferent end user in a new virtual or real environment, so that thesame or different end user may have an auditory experience that isappropriate for the new environment. The audio data may be recorded insynchrony with video data originating from virtual objects and realobjects in the ambient environment.

The augmented reality system described herein may be operated to provideimages of virtual objects intermixed with real (or physical) objects ina field of view of an end user, as well as providing virtual soundoriginating from virtual sources (either inside or outside the field ofview) intermixed with real sound originating from real (or physical)sources (either inside or outside the field of view). To this end, oneembodiment of an augmented reality system 100 constructed in accordancewith present inventions will now be described with reference to FIGS. 2and 3. The augmented reality system 100 comprises a display subsystem102, which includes a display screen 104 and a projection subsystem (notshown) that projects images onto the display screen 104.

In the illustrated embodiment, the display screen 104 is a partiallytransparent display screen through which real objects in the ambientenvironment can be seen by the end user 50 and onto which images ofvirtual objects may be displayed. The augmented reality system 100further comprises a frame structure 106 worn by an end user 50 thatcarries the partially transparent display screen 104, such that thedisplay screen 104 is positioned in front of the eyes 52 of the end user50, and in particular in the end user's 50 field of view between theeyes 52 of the end user 50 and the ambient environment.

The display subsystem 102 is designed to present the eyes 52 of the enduser 50 with photo-based radiation patterns that can be comfortablyperceived as augmentations to physical reality, with high-levels ofimage quality and three-dimensional perception, as well as being capableof presenting two-dimensional content. The display subsystem 102presents a sequence of frames at high frequency that provides theperception of a single coherent scene.

In alternative embodiments, the augmented reality system 100 may employone or more imagers (e.g., cameras) to capture and transform images ofthe ambient environment into video data, which can then be inter-mixedwith video data representing the virtual objects, in which case, theaugmented reality system 100 may display images representative theintermixed video data to the end user 50 on an opaque display surface.

Further details describing display subsystems are provided in U.S.Provisional patent application Ser. No. 14/212,961, entitled “DisplaySubsystem and Method,” and U.S. Provisional patent application Ser. No.14/331,216, entitled “Planar Waveguide Apparatus With DiffractionElement(s) and Subsystem Employing Same,” which are expresslyincorporated herein by reference.

The augmented reality system 100 further comprises one or morespeaker(s) 108 for presenting sound only from virtual objects to the enduser 50, while allowing the end user 50 to directly hear sound from realobjects. In alternative embodiments, the augmented reality system 100may comprise one or more microphones (not shown) to capture andtransform real sound originating from the ambient environment into audiodata, which can be inter-mixed with the audio data from virtual sound,in which case, the speaker(s) 108 may convey sound representative of theintermixed audio data to the end user 50.

In any event, the speaker(s) 108 are carried by the frame structure 106,such that the speaker(s) 108 are positioned adjacent (in or around) theear canals of the end user 50, e.g., earbuds or headphone. Thespeaker(s) 108 may provide for stereo/shapeable sound control. Althoughthe speaker(s) 108 are described as being positioned adjacent the earcanals, other types of speakers that are not located adjacent the earcanals can be used to convey sound to the end user 50. For example,speakers may be placed at a distance from the ear canals, e.g., using abone conduction technology. In an optional embodiment illustrated inFIG. 4, multiple spatialized speakers 108 may be located about the head54 of the end user 50 (e.g., four speakers 108-1, 108-2, 108-3, and108-4) and be configured for receiving sound from the left, right,front, and rear of the head 54 and pointed towards the left and rightears 56 of the end user 50. Further details on spatialized speakers thatcan be used for augmented reality system are described in U.S.Provisional Patent Application Ser. No. 62/369,561, entitled “MixedReality System with Spatialized Audio,” which is expressly incorporatedherein by reference.

Significantly, the augmented reality system 100 is configured forallowing the end user 50 to select one, a few, or all objects (eithervirtual or real) for recordation of sounds only from these selectedobject(s). To this end, the augmented reality system 100 furthercomprises an object selection device 110 configured for selecting one ormore real objects (i.e., real objects from which real sound originates)and virtual objects (i.e., virtual objects from which virtual soundoriginates) for recording sounds therefrom in response to input from theend user 50. The object selection device 110 may be designed toindividually select a real object or virtual object in the field of viewof the end user 50 and/or globally select a subset or all real objectsor virtual objects in the field of view of the end user 50. The objectselection device 110 may also be configured for deselecting one or morepreviously selected real objects or virtual objects in response toadditional input from the end user 50. In this case, the objectselection device 110 may be designed to deselect real objects or virtualobjects in the same manner that they were previously selected. In anyevent, the specific object is persistently selected, meaning that thespecific object remains in a selected state until intentionallydeselected.

In one embodiment, the display subsystem 102 may display athree-dimensional cursor in the field of view of the end user 50, whichin response to input into the object selection device 110, may bedisplaced in the field of view of the end user 50 for the purpose ofselecting a specific real object or virtual object in an augmentedreality scene.

For example, as shown in FIG. 5, four virtual objects (V1-V4) and tworeal objects (R1-R2) are located within a field of view 60 of thedisplay screen 104. The display subsystem 102 may display a 3D cursor 62in the field of view 60, which in the illustrated takes the form of acircle. The 3D cursor 62 may be moved over one of the objects, and inthis case, over virtual object V3, in response to input by the end user50 into the object selection device 110, thereby associating the 3Dcursor 62 with that object. The associated object can then be selected,in response to additional input by the end user 50 into the objectselection device 110. To provide visual feedback that a specific object(in this case, virtual object V3) is associated with the 3D cursor 62and is ready for selection, the associated object, or even the 3D cursor62, itself, may be highlighted (e.g., change in color or shade). Onceselected, an object may remain highlighted until it is deselected. Ofcourse, instead of virtual object V3 or in addition to the virtualobject V3, other objects in the augmented reality scene 4, includingreal objects, can be selected by placing the 3D cursor 62 over any ofthese other objects and selecting the object within the 3D cursor 62. Itshould also be appreciated that although the 3D cursor 62 in FIG. 5takes the form of a circle, the 3D cursor 62 can be any shape, includingan arrow, that can be used by the end user 50 to point to a specificobject. Any of the previously selected objects in the field of view 60can be deselected by moving the 3D cursor 62 over that previouslyselected object and deselecting it.

The object selection device 110 can take the form of any device thatallows the end user 50 to move the 3D cursor 62 over a specific objectand subsequently select that specific object. In one embodiment, theobject selection device 110 takes the form of a conventional physicalcontroller, such as a mouse, touchpad, joystick, directional buttons,etc., that can be physically manipulated to move the 3D cursor 62 over aspecific object and “clicked” to select the specific object.

In another embodiment, the object selection device 110 may comprise amicrophone and corresponding voice interpretation module that, inresponse to voice commands, can move the 3D cursor 62 over a specificobject, and then select the specific object. For example, the end user50 may speak directional commands, e.g., move left or move right, toincrementally move the 3D cursor 62 over the specific object, and thenspeak a command, such as “select,” to select the specific object.

In still another embodiment, the object selection device 110 maycomprise one or more cameras (e.g., forward-facing camera(s) 112)mounted to the frame structure 106 and a corresponding processor (notshown) capable of tracking a physical gesture by the end user 50 (e.g.,a finger movement) that correspondingly moves the 3D cursor 62 over aspecific object for selection of the specific object. For example, theend user 50 may use a finger to “drag” the 3D cursor 62 within field ofview 60 over a specific object, and then “tap” the 3D cursor 62 toselect the specific object. Or, the forward-facing camera(s) 112 may,for example, be employed to detect or infer a center of attention of theend user 50, for example, based at least in part on an orientation ofthe head 54 of the end user 50 that correspondingly moves the 3D cursor62 over a specific object for selection of the specific object. Forexample, the end user 50 may move his or her head 50 to “drag” the 3Dcursor 62 within the field of view 60 over a specific object, and thenquickly nod his or her head 50 to select the specific object.

In yet another embodiment, the object selection device 110 may comprisesone or more cameras (e.g., rearward-facing camera(s) 114 (shown in FIG.2)) and a corresponding processor that track the eyes 52 of the end user50, and in particular the direction and/or distance at which the enduser 50 is focused, which correspondingly moves the 3D cursor 62 over aspecific object for selection of that specific object. Therearward-facing camera(s) 114 may track angular position (the directionin which the eye or eyes are pointing), blinking, and depth of focus (bydetecting eye convergence) of the eyes 52 of the end user 50. Forexample, the end user 50 may move his or her eyes 54 within the field ofview to “drag” the 3D cursor over a specific object, and then blink toselect the specific object. Such eye tracking information may, forexample, be discerned by projecting light at the end user's eyes, anddetecting the return or reflection of at least some of that projectedlight. Further details discussing eye tracking devices are provided inU.S. Provisional patent application Ser. No. 14/212,961, entitled“Display Subsystem and Method,” U.S. patent application Ser. No.14/726,429, entitled “Methods and Subsystem for Creating Focal Planes inVirtual and Augmented Reality,” and U.S. patent application Ser. No.14/205,126, entitled “Subsystem and Method for Augmented and VirtualReality,” which are expressly incorporated herein by reference.

In alternative embodiments, the object selection device 110 may combinea conventional physical controller, microphone/voice interpretationmodule, and/or cameras to move and use the 3D cursor 62 to select anobject. For example, a physical controller, finger gesture, or eyemovement can be used to move the 3D cursor 62 over a specific object,and a voice command can be used to select that specific object.

Rather than use a 3D cursor 62 to select objects in the field of view ofthe end user 50, a specific object may be selected by semanticallyidentifying that specific object or selecting the object via a menudisplayed to the end user 50, in which case, the object need not be inthe field of view of the end user 50. In this case, the object selectiondevice 110 takes the form of a microphone and voice interpretationmodule if he specific object is semantically identified that translatesverbal commands provided by the end user 50. For example, if virtualobject V3 corresponds to drums, the end user 50 may speak “selectdrums,” in response to which the drums V3 will be selected. Tofacilitate selection of the object corresponding to the verbal command,semantic information identifying all relevant objects in the field ofview are preferably stored in a database, such that the description ofthe object verbally expressed by the end user 50 may be matched to thedescription of the object stored in the database. Meta data, includingsemantic information, can be previously associated with virtual objectsin a database, whereas real objects in the field of view may bepreviously mapped and associated with semantic information in the mannerdescribed in U.S. patent application Ser. No. 14/704,800, entitled“Method and System for Inserting Recognized Object Data into a VirtualWorld,” which is expressly incorporated by reference.

Alternatively, a specific object may be selected without using a 3Dcursor 62 simply by pointing or “clicking” on it using a finger gesture.In this case, the object selection device 110 may comprise one or morecameras (e.g., the forward-facing cameras 114) and a correspondingprocessor that tracks a finger gesture for selection of the specificobject. For example, the end user 50 may simply select a specific object(in this case, virtual object V3) by pointing at it, as shown in FIG. 6.In another embodiment, a specific object may be selected without using a3D cursor 62 by forming a circle or partial circle using at least twofingers (e.g., the forefinger and thumb), as shown in FIG. 7.

Although the 3D cursor 62 has been described as being used to selectonly one object at a time, in alternative or optional embodiments, the3D cursor 62 may be used to select multiple objects at one time. Forexample, as illustrated in FIG. 8, a line 64 can be drawn around a groupof objects using a 3D cursor 62, e.g., around real object R1 and virtualobjects V3 and V4, thereby selecting these group of objects. The 3Dcursor 62 can be controlled using, e.g., the same means described abovefor individually selecting objects. Alternatively, a line can be drawnaround a group of objects without the use of a 3D cursor 62, e.g., byusing a finger gesture.

In an alternative embodiment, a group of objects in a pre-definedangular range of the field of view of the end user 50 may be selected,in which case, the object selection device 110 can take the form of,e.g., a single physical or virtual selection button that can be actuatedby the end user 50 to select these objects. The angular range of thefield of view may be previously defined by the end user 50 or may bepreprogrammed into the augmented reality system 100. For example, asshown in FIG. 9, an angular range 66 of sixty degrees (±30 degrees fromcenter of field of view) is shown in the context of a 120-degree fieldof view 60. All objects within the angular range 64 of the field of view60 (in this case, virtual objects V1, V2, and V3) can be globallyselected upon actuation of the selection button, while all objectsoutside of the angular range 64 of the field of view 60 (in this case,real objects R1 and R2, and virtual object V4) will not be selected uponactuation of the selection button. In one embodiment, the end user 50may modify the angular range, e.g., by dragging one or both of the edgesdefining the angular range toward or away from the centerline of thefield of view 60 (shown by the arrows). The end user 50 may, e.g.,adjust the angular range from a minimum of 0 degrees to the entire fieldof view (e.g., 120 degrees). Alternatively, the angular range 64 of thefield of view 60 may be pre-programmed without the ability for the enduser 50 to adjust it. For example, all objects in the entirety of thefield of view 60 may be selected in response to actuation of theselection button.

The augmented reality system 100 further comprises one or moremicrophones configured for converting sounds from real objects in theambient environment to audio signals. In particular, the augmentedreality system 100 comprises a microphone assembly 116 configured forpreferentially receiving sound in a particular direction and/or at aparticular distance that corresponds to the direction and distance ofone or more real objects selected by the end user 50 via the objectselection device 110. The microphone assembly 116 comprises an array ofmicrophone elements 118 (e.g., four microphones) mounted to the framestructure 106, as illustrated in FIG. 2 (only two shown). Details on themicrophone assembly 116 will be described in further detail below. Theaugmented reality system 100 further comprises a dedicated microphone122 configured for converting speech of the end user 50 to audiosignals, e.g., for receiving commands or narration from the end user 50.

The augmented reality system 100 tracks the position and orientation ofthe selected real object(s) within a known coordinate system, so thatsounds originating from these real object(s) may be preferentially andcontinually sensed relative to non-selected real object(s) by themicrophone assembly 116 even as the position or orientation of theselected real object(s) relative to the augmented reality systemchanges. The position and location of all virtual objects in the knowncoordinate system are typically “known” to (i.e., recorded in) theaugmented reality system 100, and thus, do not generally need to beactively tracked.

In the illustrated embodiment, the augmented reality system 100 employsa spatialized audio system that renders and presents spatialized audiocorresponding to virtual objects with the known virtual locations andorientations in real and physical three-dimensional (3D) space, makingit appear to the end user 50 that the sounds are originating from thevirtual locations of the real objects, so as to affect clarity orrealism of the sound. The augmented reality system 100 tracks a positionof the end user 50 to more accurately render spatialized audio, suchthat audio associated with various virtual objects appear to originatefrom their virtual positions. Further, the augmented reality system 100tracks a head pose of the end user 50 to more accurately renderspatialized audio, such that directional audio associated with variousvirtual objects appears to propagate in virtual directions appropriatefor the respective virtual objects (e.g., out of the mouth of a virtualcharacter, and not out of the back of the virtual characters' head).Moreover, the augmented reality system 100 takes into account other realphysical and virtual objects in rendering the spatialized audio, suchthat audio associated with various virtual objects appear toappropriately reflect off of, or occluded or obstructed by, the realphysical and virtual objects.

To this end, the augmented reality system 100 further comprises ahead/object tracking subsystem 120 for tracking the position andorientation of the head 54 of the end user 50 relative to the virtualthree-dimensional scene, as well as tracking the position andorientation of real objects relative to the head 54 of the end user 50.For example, the head/object tracking subsystem 120 may comprise one ormore sensors configured for collecting head pose data (position andorientation) of the end user 50, and a processor (not shown) configuredfor determining the head pose of the end user 50 in the known coordinatesystem based on the head pose data collected by the sensor(s) 120. Thesensor(s) may include one or more of image capture devices (such asvisible and infrared light cameras), inertial measurement units(including accelerometers and gyroscopes), compasses, microphones, GPSunits, or radio devices. In the illustrated embodiment, the sensor(s)comprises the forward-facing camera(s) 112 (shown in FIG. 2). When headworn in this manner, the forward-facing camera(s) 120 is particularlysuited to capture information indicative of distance and angularposition (i.e., the direction in which the head is pointed) of the head54 of the end user 50 with respect to the environment in which the enduser 50 is located. Head orientation may be detected in any direction(e.g., up/down, left, right with respect to the reference frame of theend user 50). As will be described in further detail below, theforward-facing camera(s) 114 are also configured for acquiring videodata of real objects in the ambient environment to facilitate the videorecording function of the augmented reality system 100. Cameras may alsobe provided for tracking real objects in the ambient environment. Theframe structure 106 may be designed, such that the cameras may bemounted on the front and back of the frame structure 106. In thismanner, the array of cameras may encircle the head 54 of the end user 50to cover all directions of relevant objects.

The augmented reality system 100 further comprises a three-dimensionaldatabase 124 configured for storing a virtual three-dimensional scene,which comprises virtual objects (both content data of the virtualobjects, as well as absolute meta data associated with these virtualobjects, e.g., the absolute position and orientation of these virtualobjects in the 3D scene) and virtual objects (both content data of thevirtual objects, as well as absolute meta data associated with thesevirtual objects, e.g., the volume and absolute position and orientationof these virtual objects in the 3D scene, as well as space acousticssurrounding each virtual object, including any virtual or real objectsin the vicinity of the virtual source, room dimensions, wall/floormaterials, etc.).

The augmented reality system 100 further comprises a control subsystemthat, in addition to recording video data originating from virtualobjects and real objects that appear in the field of view, records audiodata originating from only those virtual objects and real objects thatthe end user 50 has selected via the object selection device 110. Theaugmented reality system 100 may also record meta data associated withthe video data and audio data, so that synchronized video and audio maybe accurately re-rendered during playback.

To this end, the control subsystem comprises a video processor 126configured for acquiring the video content and absolute meta dataassociated with the virtual objects from the three-dimensional database124 and acquiring head pose data of the end user 50 (which will be usedto localize the absolute meta data for the video to the head 54 of theend user 50, as described in further detail below) from the head/objecttracking subsystem 120, and rendering video therefrom, which is thenconveyed to the display subsystem 102 for transformation into imagesthat are intermixed with images originating from real objects in theambient environment in the field of view of the end user 50. The videoprocessor 126 is also configured for acquiring video data originatingfrom real objects of the ambient environment from the forward-facingcamera(s) 112, which along with video data originating from the virtualobjects, will be subsequently recorded, as will be further describedbelow.

Similarly, the audio processor 128 is configured for acquiring audiocontent and meta data associated with the virtual objects from thethree-dimensional database 124 and acquiring head pose data of the enduser 50 (which will be used to localize the absolute meta data for theaudio to the head 54 of the end user 50, as described in further detailbelow) from the head/object tracking subsystem 120, and renderingspatialized audio therefrom, which is then conveyed to the speaker(s)108 for transformation into spatialized sound that is intermixed withthe sounds originating from the real objects in the ambient environment.

The audio processor 128 is also configured for acquiring audio dataoriginating from only the selected real object(s) in the ambientenvironment from the microphone assembly 116, which along with thespatialized audio data from the selected virtual objects, along with anyresulting meta data localized to the head 54 of the end user 50 (e.g.,position, orientation, and volume data) for each virtual object, as wellas global meta data (e.g., volume data globally set by the augmentedreality system 100 or end user 50), will be subsequently recorded, aswill be further described below.

The augmented reality system 100 further comprises memory 130, arecorder 132 configured for storing video and audio in the memory 130,and a player 134 configured for retrieving the video and audio from thememory 130 for subsequent playback to the end user 50 or other endusers. The recorder 132 acquires the spatialized audio data (both audiocontent audio data and meta data) corresponding to the selected virtualand real objects from the audio processor 128, and stores this audiodata in the memory 130, and further acquires video data (both videocontent data and meta data) corresponding to the virtual and realobjects that coincide with the selected virtual and real objects.Although the player 134 is illustrated as being located in the same ARsystem 100 in which the recorder 132 and memory 130 are located, itshould be appreciated that a player may be located in a third-party ARsystem or even on smart phone or computer that plays back the video andaudio previously recorded by the AR system 100.

The control subsystem that performs the functions of the video processor126, audio processor 128, recorder 132, and player 134 may take any of alarge variety of forms, and may include a number of controllers, forinstance one or more microcontrollers, microprocessors or centralprocessing units (CPUs), digital signal processors, graphics processingunits (GPUs), other integrated circuit controllers, such as applicationspecific integrated circuits (ASICs), programmable gate arrays (PGAs),for instance, field PGAs (FPGAs), and/or programmable logic controllers(PLUs).

The functions of the video processor 126, audio processor 128, recorder132, and player 134 may be respectively performed by single integrateddevices, at least some of the functions of the video processor 126,audio processor 128, recorder 132, and/or player 134 may be combinedinto a single integrated device, or the functions of each of the videoprocessor 126, audio processor 128, recorder 132, or player 134 may bedistributed amongst several devices. For example, the video processor126 may comprise a graphics processing unit (GPU) that acquires thevideo data of virtual objects from the three-dimensional database 124and renders the synthetic video frames therefrom, and a centralprocessing unit (CPU) that acquires the video frames of real objectsfrom the forward-facing camera(s) 112. Similarly, the audio processor128 may comprise a digital signal processor (DSP) that processes theaudio data acquired from the microphone assembly 116 and user microphone122, and the CPU that processes the audio data acquired from thethree-dimensional database 124. The recording functions of the recorder132 and playback functions of the player 134 may be performed by theCPU.

Furthermore, the various processing components of the augmented realitysystem 100 may be physically contained in a distributed subsystem. Forexample, as illustrated in FIG. 10a-10d , the augmented reality system100 comprises a local processing and data module 150 operativelycoupled, such as by a wired lead or wireless connectivity 152, tocomponents mounted to the head 54 of the end user 50 (e.g., theprojection subsystem of the display subsystem 102, microphone assembly116, speakers 104, and cameras 114, 118). The local processing and datamodule 150 may be mounted in a variety of configurations, such asfixedly attached to the frame structure 106 (FIG. 10a ), fixedlyattached to a helmet or hat 106 a (FIG. 10b ), embedded in headphones,removably attached to the torso 58 of the end user 50 (FIG. 10c ), orremovably attached to the hip 59 of the end user 50 in a belt-couplingstyle configuration (FIG. 10d ). The augmented reality system 100further comprises a remote processing module 154 and remote datarepository 156 operatively coupled, such as by a wired lead or wirelessconnectivity 158, 160, to the local processing and data module 150, suchthat these remote modules 154, 156 are operatively coupled to each otherand available as resources to the local processing and data module 150.

The local processing and data module 150 may comprise a power-efficientprocessor or controller, as well as digital memory, such as flashmemory, both of which may be utilized to assist in the processing,caching, and storage of data captured from the sensors and/or acquiredand/or processed using the remote processing module 1544 and/or remotedata repository 156, possibly for passage to the display subsystem 102after such processing or retrieval. The remote processing module 154 maycomprise one or more relatively powerful processors or controllersconfigured to analyze and process data and/or image information. Theremote data repository 156 may comprise a relatively large-scale digitaldata storage facility, which may be available through the internet orother networking configuration in a “cloud” resource configuration. Inone embodiment, all data is stored and all computation is performed inthe local processing and data module 150, allowing fully autonomous usefrom any remote modules.

The couplings 152, 158, 160 between the various components describedabove may include one or more wired interfaces or ports for providingwires or optical communications, or one or more wireless interfaces orports, such as via RF, microwave, and IR for providing wirelesscommunications. In some implementations, all communications may bewired, while in other implementations all communications may bewireless, with the exception of optical fiber(s) used in the displaysubsystem 102. In still further implementations, the choice of wired andwireless communications may be different from that illustrated in FIGS.10a-10d . Thus, the particular choice of wired or wirelesscommunications should not be considered limiting.

In the illustrated embodiment, light source(s) and drive electronics(not shown) of the display subsystem 102, and the processing componentsof the had/object tracking subsystem 120 and object selection device110, and the DSP of the audio processor 128 may be contained in thelocal processing and data module 150. The GPU of the video processor 126and CPU of the video processor 126 and audio processor 128 may becontained in the remote processing module 154, although in alternativeembodiments, these components, or portions thereof may be contained inthe local processing and data module 150. The three-dimensional database124 and memory 130 can be associated with the remote data repository156.

The audio processor 128 illustrated in FIG. 3 will be described infurther detail in processing and recording audio data from virtual andreal objects selected by the end user 50. In the exemplary scenarioshown in FIG. 11, the end user 50 (e.g., a parent) desires to record thesounds from a four-piece band, including a virtual drummer V2 object, areal vocalist R2, e.g., a child, a virtual guitarist V3, and a virtualbass guitarist V4, desires to monitor news or sports on a virtualtelevision V1 without recording the sounds from the virtual television,and further does not desire to record sounds from a real kitchen R1,e.g., someone cooking.

In the embodiment illustrated in FIG. 12, the functions of the audioprocessor 128 are distributed between a CPU 180, which processes theaudio originating from virtual objects, and a DSP 182, which processesthe audio originating from real objects. The CPU 180 comprises one ormore special effects modules 184 (in this case, special effects modules1-n) configured for generating spatialized audio data EFX-V1-EFX-Vncorresponding to the individual virtual objects V1-Vn. To this end, thespecial effects modules 184 acquire audio content data AUD-V1 to AUD-Vnand absolute meta data MD_(a)-V1 to MD_(a)-Vn corresponding to thevirtual objects V1-Vn from the 3D database 124, as well as head posedata from the head/object tracking subsystem 120, localizes the absolutemeta data MD_(a)-V1 to MD_(a)-Vn to the head 54 of the end user 50 basedon the head pose data, and applies the localized meta data (e.g.,position, orientation, and volume data) to the audio content data togenerate the spatialized audio data for the virtual objects V1-Vn.

The CPU 180 further comprises a mixer 186 configured for mixing thespatialized audio data EFX-V1-EFX-Vn received from the respectivespecial effects module(s) 184 to obtain the mixed audio data EFX, and aglobal special effects module 188 configured for applying global metadata MD-OUT (e.g., global volume) to the mixed spatialized audio data toobtain final spatialized audio AUD-OUT EFX that is output throughmultiple sound channels to the speakers 108.

Significantly, the special effects module(s) 184 is configured forsending the audio content data originating from the virtual objects thathave been selected by the end user 50 via the object selection device110 and the meta data (localized and/or absolute) corresponding to theseselected virtual objects to the recorder 132 for storage in the memory130 (shown in FIG. 2), and the global special effects module 188 isconfigured for sending the global meta data MD-OUT to the recorder 132for storage in the memory 130. In the exemplary embodiment, the virtualaudio content data AUD-V2 (i.e., virtual drummer), AUD-V3 (i.e., thevirtual guitarist), AUD-V4 (i.e., virtual bass guitarist) are selectedfor recording, while the audio content data AUD-V1 (i.e., the virtualtelevision) is not selected for recording. Thus, the audio content dataAUD-V2, AUD-V3, and AUD-V4 and the corresponding localized meta dataMD-V2, MD-V3, and MD-V4 is stored in the memory 130, as shown in FIG.13.

In an alternative embodiment, instead of, or in addition to,individually storing the audio content data from the selected virtualobjects and the corresponding localized/absolute meta data and globalmeta data within the memory 130, the CPU 180 outputs spatialized audiogenerated by additionally mixing the spatialized audio data EFX-V2,EFX-V3, EFX-V4 corresponding to only the selected virtual objectsAUD-V2, AUD-V3, and AUD-V4 and applying global meta data MD-OUT to thismixed spatialized audio data to obtain spatialized audio that includesonly the audio from the selected virtual objects AUD-V2, AUD-V3, andAUD-V4. However, in this case, an additional audio mixing function willneed to be incorporated into the CPU 180.

The DSP 182 is configured for processing audio signals acquired from themicrophone assembly 116 and outputting audio signals preferentiallyrepresenting sounds received by the microphone assembly 116 from aparticular direction, and in this case, from the direction of each realobject selected by the end user 50 via the object selection device 110.Because the position and/or orientation of the real object may moverelative to the head 54 of the end user 50, real object tracking datamay be received from the head/object tracking subsystem 120, such thatany change in the position and/or orientation of the real objectrelative to the head 54 of the end user 50 may be taken into account, sothat the DSP 182 may dynamically modify the audio output topreferentially represent sounds received by the microphone assembly 116from the direction of the relatively moving real object. For example, ifthe end user 50 moves his or her head 54 counter-clockwise ninetydegrees relative to the orientation of the head 54 when the real objectwas selected, the preferential direction of the audio output from theDSP 182 can be dynamically shifted clock-wise ninety degrees.

With reference to FIG. 14, the microphone elements 118 of the microphoneassembly 116 take the form of a phased array of microphone elements (inthis case, microphone elements M1-Mn), each of which is configured fordetecting and converting ambient sound signals into an audio signal. Inthe illustrated embodiment, the microphone elements 118 are digital innature, and thus, convert the ambient sound signal into digital audiosignals, and in this case pulse density modulation (PDM) signals.Preferably, the microphone elements 118 are spaced from each other tomaximize directionality of the audio output. For example, as shown inFIG. 2, two of the microphone elements 118 may be mounted to each arm ofthe frame structure 106, although more than two, such as four microphoneelements 118 may be mounted to each arm of the frame structure 106.Alternatively, the frame structure 106 may be designed, such that themicrophone elements 118 may be mounted on the front and back of theframe structure 106. In this manner, the array of microphone elements118 may encircle the head 54 of the end user 50 to cover all directionsof potential sources of sound.

The microphone assembly 116 further comprises a plurality of digitalmicrophone interfaces (DMICs) 190 (in this case, DMIC1-DMICn, one foreach microphone element M) that are configured for respectivelyreceiving the respective digital audio signals from the correspondingmicrophone elements 118 and performing a digital filter operationreferred to as “decimation” to convert the digital audio signals fromthe PDM format to a more easily manipulatable pulse code modulation(PCM). Each of the DMICs 190 also performs fixed gain control on thedigital audio signals.

The DSP 182 comprises a plurality of audio processing modules 200, eachof which is configured for processing the digital audio signal output bythe microphone assembly 116, and outputting a directional audio signalAUD-R (one of directional audio signals AUD-R1 to AUD-Rm) thatpreferentially represents sound received by the microphone assembly 116in the direction of a selected real object (one of R1 to Rm). Thedirectional audio signals AUD-R1 to AUD-Rm output by the respectiveaudio processing modules 200 are combined into a directional audiooutput AUD-OUT MIC, which preferentially represents sound originatingfrom all selected real objects. In the illustrated embodiment, the DSP182 creates one instance of an audio processing module 200 for each realobject selected by the end user 50 via the object selection device 110.

To this end, each of the audio processing modules 200 comprisesprocessing parameters in the form of a plurality of delay elements 194(in this case, delay elements D1-Dn, one for each microphone element M),a plurality of gain elements 196 (in this case, gain elements G1-Gn, onefor each microphone element M), and a summer 198. The delay elements 194respectively apply delay factors to the amplified digital signalsreceived from the corresponding gain amplifiers 192 of the microphoneassembly 116, and the gain elements 196 respectively apply gain factorsto the delayed digital signals. The summer 198 (S) adds the gainadjusted and delayed signals to respectively generate the respectivedirectional audio signal AUD-R.

The microphone elements 118 are spatially arranged and the delayelements 194 and gain elements 196 of each audio processing module 200are applied to the digital audio signals received from the microphoneassembly 116 in a manner that results in the receipt of ambient sound inaccordance with a directional polar pattern (i.e., sounds arriving froma particular angular direction or directions will be emphasized morethan sounds arriving from other angular directions). The DSP 182 isconfigured for modifying the directionality of the directional audiosignals AUD-R1 to AUD-Rm, and thus the combined directional audio outputAUD-OUT MIC by changing the delay factors of the delay elements 194 andthe gain factors of the gain elements 196.

Thus, it can be appreciated that the directionality of the audio outputAUD-OUT MIC is modified based on the selected real object, e.g., thedirection or directions from which sound is preferentially received maybe set along the direction of the selected real object or sources.

For example, with reference to FIG. 15a , if two real objects R_(a) andR_(b) respectively along two particular directions D_(a) and D_(b) areselected, the DSP 182 will generate two instances of the audioprocessing modules 200, and within each of these audio processingmodules 200, select the respective delay factors and gain factors forall of the delay elements 194 and gain elements 196 in each audioprocessing module 200, such that a receipt gain pattern having two lobesaligned with the directions D_(a) and D_(b) of the real objects R_(a)and R_(b) is generated. If the orientation of the real objects R_(a) andR_(b) relative to the head 54 of the end user 50 changes, the particulardirections of the real objects Ra and Rb may change, in which case, theDSP 182 may select different delay factors and gain factors for all ofthe delay elements 194 and gain elements 196 in each audio processingmodule 200, such that the receipt gain pattern has two lobes alignedwith directions D₀ and D_(d), as illustrated in FIG. 15 b.

To facilitate such dynamic modification of the directionality of theaudio output AUD-OUT MIC, different sets of delay/gain values and thecorresponding preferential directions may be stored in memory 130 foraccess by the DSP 182. That is, the DSP 182 matches the direction ofeach selected real object R with the closest directional value stored inmemory 130, and selects the corresponding set of delay/gain factors forthat selected direction.

It should be noted that although the microphone elements 118 aredescribed as being digital, the microphone elements 118 mayalternatively be analog. Furthermore, although the delay elements 194,gain elements 196, and summer 198 are disclosed and illustrated as beingsoftware components that reside within the DSP 182, any one or more ofthe delay elements 194, gain elements 196, and summer 198 may compriseanalog hardware components that reside outside of, but under control of,the DSP 182. However, the use of software-based audio processing modules200 allows sound from several distinct real objects to be preferentiallyreceived and processed at the same time.

Referring back to FIG. 12, the DSP 182 also receives voice data from theuser microphone 122 and combines that with the directional audio outputAUD-OUT MIC. In an optional embodiment, the DSP 182 is configured forperforming acoustic echo cancellation (AEC) and noise suppression (NS)functions with respect to sounds from the speakers 108 originating fromthe virtual objects. That is, the microphone assembly 116 may sensesounds emitted by the speakers 108 even though the direction in whichthe sound is preferentially received may not coincide with the speakers108. To this end, the spatialized audio data output by the globalspecial effects module 188 into the speakers 108 is also input into theDSP 182, which uses the spatialized audio data to suppress the resultingsounds output by the speakers 108 (considered as noise) into themicrophone assembly 116 and cancel any echoes resulting from feedbackfrom the speakers 108 into the microphone assembly 116.

Significantly, the DSP 182 is further configured for sending thedirectional audio output AUD-OUT MIC and localized meta data (e.g., thelocation and orientation of the real object from which the directionalaudio output AUD-OUT MIC originated) to the recorder 132 for storage asaudio content data in the memory 130 (shown in FIG. 2). In the exemplaryembodiment illustrated in FIG. 11, the localized meta data correspondsto the real object AUD-R2 (i.e., the real vocalist). Thus, thedirectional audio output AUD-OUT MIC (which preferentially correspondsto the real object AUD-R2) and the corresponding localized meta dataMD-R2 is stored in the memory 130, as shown in FIG. 13.

In an optional embodiment, the directional audio output AUD-OUT MIC(which may be spatialized) may be input into the speakers 108 or otherspeakers for playback to the end user 50. The directional audio outputAUD-OUT MIC may be spatialized in the same manner as the spatializedaudio data originating from virtual sources to make it appear to the enduser 50 that the sounds are originating from the locations of the realobjects, so as to affect clarity or realism of the sound. That is, thelocalized meta data (e.g., the location and orientation of the realobject from which the directional audio output AUD-OUT MICpreferentially originated) may be applied to the directional audiooutput AUD-OUT MIC to obtain spatialized audio data.

In another optional embodiment, the sound originating from a real objector even a virtual object selected by the end user 50 may be profiled. Inparticular, the DSP 182 may analyze and compare the characteristics ofthe sound from the selected object to the characteristics of soundsoriginating from other real objects in order to determine a type of atarget sound. The DSP 182 can then, if desired, include all audio dataoriginating from these real objects in the directional audio outputAUD-OUT MIC for recording by the recorder 132 into the memory 130 (shownin FIG. 2). For example, if the end user 50 selected any of the musicalobjects (AUD-V2, AUD-V3, AUD-V4, AUD-R2), the DSP 182 can control themicrophone assembly 116 to preferentially sense all musical realobjects.

In the illustrated embodiment, the DSP 182 continues to output thedirectional audio output AUD-OUT MIC to the recorder 130 for recordationin the memory 130 even if the real object 198 selected by the end user50 moves out of the field of view of the display subsystem 102 (asindicated by the real object tracking data received from the head/objecttracking subsystem 120. In an alternative embodiment, the DSP 182 ceasesto output the directional audio output AUD-OUT MIC to the recorder 130for recordation in the memory 130 as soon as the real object 198selected by the end user 50 moves out of the field of view of thedisplay subsystem 102, and reinitiates output of the directional audiooutput AUD-OUT MIC to the recorder 130 for recordation in the memory 130as soon as the real object 198 selected by the end user 50 moves backinto the field of view of the display subsystem 102.

In a similar manner that the audio processor 128 (in the illustratedembodiment, the CPU 180 and DSP 182) sends the audio content dataoriginating from the selected virtual objects and real objects (in theexemplary case, audio content data AUD-V2, AUD-V3, and AUD-V4, andAUD-MIC) and the localized meta data (in the exemplary case, MD-V2,MD-V3, MD-V4, and MD-R2) and global meta data (MD-OUT) to the recorder132 for storage in the memory 130, the video processor 126 may sendvideo content data originating from virtual objects and real objects (inthe exemplary case, video content data VID-V2, VID-V3, VID-V4, andVID-R2), as illustrated in FIG. 13. In the case of virtual objects, thevideo processor 126 simply acquires virtual objects from the 3D database124 without further processing and sends these virtual objects to therecorder 132 for storage in the memory 130. In the case of real objects,the video processor 126 may extract or “cut off” any of the selectedreal objects from the video acquired from the camera(s) 112, and storesthese real objects as virtual objects in the memory 130. In theexemplary case illustrated in FIG. 11, the video for the real vocalistR2 may be recorded as a virtual object VID-R2. In an optionalembodiment, the video processor 126 sends the entire video (includingvideo corresponding to non-selected virtual and real objects) acquiredfrom the camera(s) 112 to the recorder 132 for storage in the memory130.

The player 134 is configured for playing back the video and/or audiorecorded within the memory 130 to a playback user 50′ (shown in FIG. 16a), which may be the original end user 50 that recorded the video/audioor a third-party user. The audio/video may be selectively played back bythe player 134 in response to commands given by the playback user 50′,e.g., voice commands via the user microphone 122. For example, theplayback user 50′ may turn the virtual audio playback on or off using a“virtual audio on/off” command, or turn the virtual video playback on oroff using a “display on/off” command, or turn the real audio playback onor off using a “real-audio on/off” command.

In the illustrated embodiment, the audio processor 128 retrieves theaudio content data and meta data (corresponding to the selected virtualand real objects) from the memory 130, renders the spatialized audiofrom the audio content data and meta data, and conveys the spatializedaudio to the player 134 for play back to the playback user 50′ via thespeakers 108. In the alternative embodiment where the mixed spatializedaudio data (instead of content and meta data) is stored, the player 134may simply acquire the audio data from the memory 130 for play back tothe playback user 50′ without re-rendering or otherwise furtherprocessing the audio data.

Furthermore, in the illustrated embodiment, the video processor 126retrieves the video content data and meta data (corresponding to theselected virtual and real objects), renders the video from the videocontent data and meta data, conveys the video to the player 134 forplayback to the playback user 50′ via the display subsystem 102 insynchrony with the playback of the audio via the speakers 108.Optionally, in the case where all of the video data captured by thecamera(s) 112 is stored, the player 134 may simply acquire the videodata from the memory 130 for play back to the playback user 50′ withoutrendering or otherwise further processing video data. The augmentedreality system 10 may provide the playback user 50′ with an option toeither play back only the video corresponding to the selected virtualand real objects or play back the full video captured by the camera(s)112.

In one embodiment, the current head pose of the playback user 50′ is nottaken into account during playback of the video/audio. Instead, thevideo/audio is played back to the playback user 50′ using the head poseoriginally detected during the recording of the video/audio data, whichwill be reflected in the localized meta data stored along with theaudio/video content data within the memory 130, or if the mixedspatialized audio is recorded without meta data, the head pose will bereflected within the mixed spatialized audio stored in the memory 130.In this case, the playback user 50′ will experience the video/audio inthe same manner as that the original end user 50 experienced thevideo/audio, with the exception that only the audio, and optionally onlythe video, originating from the virtual and real objects selected by theoriginal end user 50 will be played back. In this case, the playbackuser 50′ may not be immersed in augmented reality, since the head poseof the playback user 50′ will be taken into account. Rather, theplayback user 50′ may experience the audio playback using headset (soaudio will not be affected by the environment), or the playback user 50′may experience the audio playback in a quiet room.

In an alternative embodiment, the current head pose of the playback user50′ may be taken into account during playback of the video/audio. Inthis case, the head pose of the playback user 50′ during recording ofthe video/audio need not to be incorporated into the meta data storedalong with the video/audio content data in the memory 130, since thecurrent head pose of the playback user 50′ detected during playback willbe used to re-render the video/audio data. Instead, the absolute metadata (e.g., the volume and absolute position and orientation of thesevirtual objects in the 3D scene, as well as space acoustics surroundingeach virtual object, including any virtual or real objects in thevicinity of the virtual source, room dimensions, wall/floor materials,etc.) stored in the memory 130 will be localized to the head pose of theplayback user 50′ using the current head pose of the playback user 50′,and then used to render the audio/video. Thus, the playback user 50′will be immersed in augmented reality during playback of thevideo/audio.

The playback user 50′ may experience the augmented reality in theoriginal spatial environment in which the video/audio was recorded(e.g., the “same physical room”) or may experience the augmented realityin a new physical or virtual spatial environment (e.g., a “differentphysical or virtual room”).

If the augmented reality is experienced by the playback user 50′ in theoriginal spatial environment in which the video/audio was recorded, theabsolute meta data associated with the selected objects need not bemodified for accurate playback of the spatialized audio. In contrast, ifthe augmented reality is experienced by the playback user 50′ in a newspatial environment, the absolute meta data associated with the objectsmay need to be modified for accurate rendering of the audio/video in thenew spatial environment.

For example, in the exemplary embodiment, the audio/video content fromthe virtual objects AUD-V2 (i.e., virtual drummer), AUD-V3 (i.e., thevirtual guitarist), AUD-V4 (i.e., virtual bass guitarist), and realobject (i.e., real vocalist) may be recorded in a small room 250, asillustrated in FIG. 16a . The previously recorded audio from the virtualobjects AUD-V2 (i.e., virtual drummer), AUD-V3 (i.e., the virtualguitarist), AUD-V4 (i.e., virtual bass guitarist), and real object(i.e., real vocalist) may be played back in a concert hall 252, asillustrated in FIG. 16b . The augmented reality system 10 may repositionthe objects anywhere in the concert hall 252, and absolute meta dataincluding the new positions of each object in the concert hall 252, aswell as the space acoustics surrounding each object in the concert hall252, may be generated or otherwise acquired. This absolute meta data canthen be localized using current head pose of the playback user 50′, andthen used to render the audio and video in the concert hall 252 forplayback to the playback user 50′.

Having described the arrangement and function of the augmented realitysystem 100, one method 300 of using the augmented reality system 100 toselect at least one object and record audio and video from theseselected object(s) will now be described with respect to FIG. 17.

First, the end user 50 persistently selects at least one object (e.g.,real and/or virtual) in a spatial environment via the object selectiondevice 110 (step 302). The object(s) can be selected in the field ofview 60 of the end user 50, e.g., by moving a three-dimensional cursor62 in the field of view 60 of the end user 50 and selecting theobject(s) with the three-dimensional cursor 62 (shown in FIG. 5). Or,the object(s) can be selected using hand gestures (shown in FIG. 6 or 7)or using voice commands. Multiple objects may be individually selected,or may be globally selected, e.g., by drawing a line 64 around theobjects (shown in FIG. 8) or by defining an angular range 66 of thefield of view 60 of the end user 50 (which may be less than the entireangular range of the field of view 60 of the end user 50), and selectingall of the objects in the defined angular range 66 of the field of view60 of the end user 50 (shown in FIG. 9).

Next, the audio and video content for all virtual objects within thespatial environment, as well as the absolute meta data associated withthe virtual objects, are acquired (step 304). Next, current head pose ofthe end user 50 is tracked (step 306), and the absolute meta data islocalized to the head 54 of the end user 50 using the current head posedata (step 308), and applied to the audio and video content of thevirtual objects to obtain video data and spatialized audio data for allof the respective virtual objects (step 310). The spatialized audio datafor all of the respective virtual objects in the 3D scene are mixed(step 312), and global meta data is applied to the mixed spatializedaudio data to obtain final spatialized audio for all virtual objects inthe 3D scene (step 314), which is then transformed into sound forperception by the end user 50 (step 316). Next, the video data obtainedat step 310 is transformed into image frames for perception by the enduser 50 (step 318). Next, the audio/video content and all associatedmeta data (both absolute and localized meta data) for all virtualobject(s) selected by the end user 50 at step 302 are recorded (step320).

In parallel with steps 304-320, the position and/or orientation of theselected real object(s) relative to the head 54 of the end user 50 istracked (step 322), and sound originating from the selected realobject(s) is preferentially sensed based on the tracked position andorientation of the real object(s) (step 324). Next, images of theselected real object(s) are captured (step 326), and optionallytransformed into virtual video content. Next, the audio contentassociated with the preferentially sensed sound from the selected realobject(s) and the video content associated with the captured images ofthe selected real object(s), as well as all associated meta data(location and orientation of the real object(s)), for each of theselected real object(s) are recorded (step 328).

One method 400 of using the augmented reality system 100 to play backpreviously recorded audio and video of at least one object to a playbackuser 50′ will now be described with respect to FIG. 18. Such audio andvideo may have been previously recorded as audio content data and videocontent data in the manner described above in the method 300 of FIG. 17.The object(s) may be real and/or virtual, and may have been persistentlyselected by the end user 50. In the exemplary method 400, the audio andvideo has been previously recorded in an original spatial environment,such as a small room 250, and playback in a new spatial environmentdifferent from the original spatial environment, such as a concert hall252, as described with respect to FIGS. 16a and 16 b.

First, the previously recorded audio content data and video content datais acquired (step 402). If the new spatial environment is at leastpartially virtual, additional virtual content (either audio or video)associated with the new spatial environment may also be acquired. Then,the object(s) are re-positioned within the new spatial environment,which may be in response to input from the playback user 50′ (step 404).Then, absolute meta data corresponding to the object(s) positioned inthe new spatial environment is acquired (step 406), the head pose of theplayback user 50′ is tracked in the new spatial environment (step 408),and the absolute meta data is localized to the playback user 50′ basedon the tracked head pose of the playback user 50′ (step 410). Next, theaudio and video is rendered from the retrieved audio content data andvideo content data based on the localized meta data in the new spatialenvironment (step 412). The rendered audio and video are thenrespectively transformed into sound and image frames for synchronousperception by the playback user 50′ (step 414).

In the foregoing specification, the invention has been described withreference to specific embodiments thereof. It will, however, be evidentthat various modifications and changes may be made thereto withoutdeparting from the broader spirit and scope of the invention. Forexample, the above-described process flows are described with referenceto a particular ordering of process actions. However, the ordering ofmany of the described process actions may be changed without affectingthe scope or operation of the invention. The specification and drawingsare, accordingly, to be regarded in an illustrative rather thanrestrictive sense.

What is claimed is:
 1. A method for reproducing audio-visual effectswith spatialized audio in an augmented reality environment, comprising:identifying audio data and first metadata associated with the audio datacaptured in a first augmented reality environment, wherein the audiodata is perceived by a first user at a first user location in a firstenvironment as emanating from an object in the first augmented realityenvironment, the first metadata pertains to the first user and at leasta portion of the first augmented reality environment in which the audiodata is recorded, and the first augmented reality environment is createdfrom a first real-world environment portion by an augmented realitysystem, rendering the audio data into spatialized audio for a seconduser or the first user at a second user location in a second augmentedreality environment at least by localizing the first metadata to thefirst or second user at the second user location to generate firstlocalized metadata based at least in part upon second metadata, whereinthe second metadata pertains to a positional or orientationalcharacteristic detected by the virtual image generation system for thefirst or the second user at the second user location in the secondaugmented reality environment; and presenting the spatialized audio andat least one virtual object pertaining to at least the object insynchrony to the user based at least in part upon the first metadata andthe second metadata.
 2. The method of claim 1, comprising: capturingreal visual data of at least a portion the first real-world environmentportion in the first augmented reality environment, wherein the realvisual data comprises real image data or real video data for the firstreal-world environment, wherein the real image data comprises real imagecontent data and real image metadata associated with the real imagecontent data, and the real video data comprises real video content dataand real video metadata associated with the real video content data; andintermixing the real visual data with virtual visual data intointermixed visual data, wherein the virtual visual data comprisesvirtual image data or virtual video data for the first virtualenvironment portion in the first augmented reality environment, and thevirtual visual data is generated by the augmented reality system.
 3. Themethod of claim 1, identifying the audio data comprising: in response toa user input received at the augmented reality system, selecting, at anobject selection device of the augmented reality system, the object froma plurality of objects in the first augmented reality environment,wherein the plurality of objects comprises at least one real object andat least one virtual object.
 4. The method of claim 3, identifying theaudio data further comprising: in response to a separate user input,deselecting a first object that has been selected with the objectselection device of the augmented reality system, wherein the objectselection device includes at least one of a physical controller thatcontrols a cursor displayed to the user, an audio data capturing device,a voice interpretation module that interprets one or more voicecommands, a first visual data detecting device that tracks gestures, asecond visual data detecting device that tracks a position or anorientation of an eye of the user, or any combinations thereof.
 5. Themethod of claim 1, further comprising: selecting the object frommultiple objects in the first augmented reality environment; tracking aposition or orientation of the object with the augmented reality system;and preferentially sensing sound emanating from the object based atleast in part upon the position or the orientation of the object,wherein the audio data is preferentially recorded for the object overanother object in a first direction, at a first object location, or afirst object stance in the first augmented reality environment.
 6. Themethod of claim 5, further comprising: continually and preferentiallydetecting, at a position and pose tracking device of the augmentedreality system, a position and a pose or orientation of the first useror a portion of the first user relative to the object in the firstaugmented reality environment; updating the first metadata pertaining tothe first user into updated first metadata based at least in part aresult of continually and preferentially detecting the position and thepose or orientation of the first user or the portion of the first userrelative to the object; and updating the first localized metadata basedat least in part upon the updated first metadata.
 7. The method of claim6, wherein the spatialized audio is perceived by the first or the seconduser in the second augmented reality environment as reflecting off of,occluded or obstructed by a first real object at a first real objectlocation in the second augmented reality environment.
 8. The method ofclaim 1, further comprising: rendering the spatialized audio for a firstvirtual object at a first virtual object location in the secondaugmented reality environment relative to the second user location sothat the spatialized audio is perceived by the first or the second userat the second user location in the second augmented reality environmentas emanating from the first virtual object at the first virtual objectlocation in the second augmented reality environment, wherein the audiodata was captured as emanating from the object in the first augmentedreality environment, and the object is rendered as the first virtualobject in the second augmented reality environment by the augmentedreality system;
 9. The method of claim 1, further comprising: capturingthe audio data in the first environment with at least an audioprocessing module that comprises a microphone, a delay element, and again element and operates based at least in part upon a polar patternstored in the augmented reality system; capturing image or video contentdata with an image capturing device of the augmented reality system;capturing image or video metadata associated with the image or videocontent data with a position device or a tracking device of theaugmented reality system; and determining audio metadata pertaining tothe audio data at least by correlating the audio data with the image orvideo content data or the image or video metadata.
 10. The method ofclaim 1, wherein localizing the first metadata to the first or seconduser at the second user location comprises: identifying relativepositioning or orientation data pertaining to a position or anorientation of the object relative to the first use location or a firstpose of the first user in the first environment; capturing the audiodata perceived by the first user at the first user location at least byusing a microphone element, a delay element, a gain element, and a polardirectional pattern of the augmented reality system in the firstenvironment; correlating the relative positioning or orientation datawith the audio data; identifying the positional or orientationalcharacteristic at the second user location in the second augmentedreality environment; and localizing the first metadata to the first orsecond user at the second user location at least by applying therelative positioning or orientation data to a head of the first orsecond user based at least in part upon the positional or orientationalcharacteristic at the second user location.
 11. An augmented realitysystem, comprising: an audio processing module comprising an audiosignal processor; an image processing module comprising a graphicsprocessing unit and coupled to the audio processing module to produceaudio-visual contents to a first user; a virtual image generation modulecomprising at least a microprocessor and coupled to the audio processingmodule and the image processing module to present virtual contents tothe first user, wherein the augmented reality system is configured toperform a set of acts, the set of acts comprising: identifying audiodata and first metadata associated with the audio data captured in afirst augmented reality environment, wherein the audio data is perceivedby a first user at a first user location in a first environment asemanating from an object in the first augmented reality environment, thefirst metadata pertains to the first user and at least a portion of thefirst augmented reality environment in which the audio data is recorded,and the first augmented reality environment is created from a firstreal-world environment portion by the augmented reality system,rendering the audio data into spatialized audio for a second user or thefirst user at a second user location in a second augmented realityenvironment at least by localizing the first metadata to the first orsecond user at the second user location to generate first localizedmetadata based at least in part upon second metadata, wherein the secondmetadata pertains to a positional or orientational characteristicdetected by the virtual image generation system for the first or thesecond user at the second user location in the second augmented realityenvironment; and presenting the spatialized audio and at least onevirtual object pertaining to at least the object in synchrony to theuser based at least in part upon the first metadata and the secondmetadata.
 12. The augmented reality system of claim 11, furthercomprising an image or video capturing device, wherein the set of actsfurther comprises: capturing, at the image or video capturing device,real visual data of at least a portion the first real-world environmentportion in the first augmented reality environment, wherein the realvisual data comprises real image data or real video data for the firstreal-world environment, wherein the real image data comprises real imagecontent data and real image metadata associated with the real imagecontent data, and the real video data comprises real video content dataand real video metadata associated with the real video content data; andintermixing, at the image processing module, the real visual data withvirtual visual data into intermixed visual data, wherein the virtualvisual data comprises virtual image data or virtual video data for thefirst virtual environment portion in the first augmented realityenvironment, and the virtual visual data is generated by the augmentedreality system.
 13. The augmented reality system of claim 11, furthercomprises a user input module that receives an input from users, whereinidentifying the audio data comprises: in response to a user inputreceived at the augmented reality system, selecting, at an objectselection device of the augmented reality system, the object from aplurality of objects in the first augmented reality environment, whereinthe plurality of objects comprises at least one real object and at leastone virtual object.
 14. The augmented reality system of claim 13,wherein identifying the audio data further comprises: in response to aseparate user input, deselecting a first object that has been selectedwith the object selection device of the augmented reality system,wherein the object selection device includes at least one of a physicalcontroller that controls a cursor displayed to the user, an audio datacapturing device, a voice interpretation module that interprets one ormore voice commands, a first visual data detecting device that tracksgestures, a second visual data detecting device that tracks a positionor an orientation of an eye of the user, or any combinations thereof.15. The augmented reality system of claim 11, further comprising a userinput module and a position or orientation tracking module, wherein theaugmented reality system is further configured to perform the set ofacts, the set of acts comprising: selecting the object from multipleobjects in the first augmented reality environment; tracking a positionor orientation of the object with the augmented reality system; andpreferentially sensing sound emanating from the object based at least inpart upon the position or the orientation of the object, wherein theaudio data is preferentially recorded for the object over another objectin a first direction, at a first object location, or a first objectstance in the first augmented reality environment.
 16. The augmentedreality system of claim 15, the set of acts performed by the augmentedreality system further comprising: continually and preferentiallydetecting, at a position and pose tracking device of the augmentedreality system, a position and a pose or orientation of the first useror a portion of the first user relative to the object in the firstaugmented reality environment; updating the first metadata pertaining tothe first user into updated first metadata based at least in part aresult of continually and preferentially detecting the position and thepose or orientation of the first user or the portion of the first userrelative to the object; and updating the first localized metadata basedat least in part upon the updated first metadata.
 17. The augmentedreality system of claim 16, wherein the spatialized audio is perceivedby the first or the second user in the second augmented realityenvironment as reflecting off of, occluded or obstructed by a first realobject at a first real object location in the second augmented realityenvironment.
 18. The augmented reality system of claim 11, the set ofacts performed by the augmented reality system further comprising:rendering the spatialized audio for a first virtual object at a firstvirtual object location in the second augmented reality environmentrelative to the second user location so that the spatialized audio isperceived by the first or the second user at the second user location inthe second augmented reality environment as emanating from the firstvirtual object at the first virtual object location in the secondaugmented reality environment, wherein the audio data was captured asemanating from the object in the first augmented reality environment,and the object is rendered as the first virtual object in the secondaugmented reality environment by the augmented reality system;
 19. Theaugmented reality system of claim 11, the set of acts performed by theaugmented reality system further comprising: capturing the audio data inthe first environment with at least an audio processing module thatcomprises a microphone, a delay element, and a gain element and operatesbased at least in part upon a polar pattern stored in the augmentedreality system; capturing image or video content data with an imagecapturing device of the augmented reality system; capturing image orvideo metadata associated with the image or video content data with aposition device or a tracking device of the augmented reality system;and determining audio metadata pertaining to the audio data at least bycorrelating the audio data with the image or video content data or theimage or video metadata.
 20. The augmented reality system of claim 11,the set of acts performed by the augmented reality system furthercomprising: identifying relative positioning or orientation datapertaining to a position or an orientation of the object relative to thefirst use location or a first pose of the first user in the firstenvironment; capturing the audio data perceived by the first user at thefirst user location at least by using a microphone element, a delayelement, a gain element, and a polar directional pattern of theaugmented reality system in the first environment; correlating therelative positioning or orientation data with the audio data;identifying the positional or orientational characteristic at the seconduser location in the second augmented reality environment; andlocalizing the first metadata to the first or second user at the seconduser location at least by applying the relative positioning ororientation data to a head of the first or second user based at least inpart upon the positional or orientational characteristic at the seconduser location.